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The evolution of multicellular motile organisms from unicellular ancestors required the utilization of previously evolved tactic behavior in a multicellular context. Volvocine green algae are uniquely suited for studying tactic responses during the transition to multicellularity because they range in complexity from unicellular to multicellular genera. Phototactic responses are essential for these flagellates because they need to orientate themselves to receive sufficient light for photosynthesis, but how does a multicellular organism accomplish phototaxis without any known direct communication among cells? Several aspects of the photoresponse have previously been analyzed in volvocine algae, particularly in the unicellular alga Chlamydomonas.
In this study, the phototactic behavior in the spheroidal, multicellular volvocine green alga Volvox rousseletii (Volvocales, Chlorophyta) was analyzed. In response to light stimuli, not only did the flagella waveform and beat frequency change, but the effective stroke was reversed. Moreover, there was a photoresponse gradient from the anterior to the posterior pole of the spheroid, and only cells of the anterior hemisphere showed an effective response. The latter caused a reverse of the fluid flow that was confined to the anterior hemisphere. The responsiveness to light is consistent with an anterior-to-posterior size gradient of eyespots. At the posterior pole, the eyespots are tiny or absent, making the corresponding cells appear to be blind. Pulsed light stimulation of an immobilized spheroid was used to simulate the light fluctuation experienced by a rotating spheroid during phototaxis. The results demonstrated that in free-swimming spheroids, only those cells of the anterior hemisphere that face toward the light source reverse the beating direction in the presence of illumination; this behavior results in phototactic turning. Moreover, positive phototaxis is facilitated by gravitational forces. Under our conditions, V. rousseletii spheroids showed no negative phototaxis.
On the basis of our results, we developed a mechanistic model that predicts the phototactic behavior in V. rousseletii. The model involves photoresponses, periodically changing light conditions, morphological polarity, rotation of the spheroid, two modes of flagellar beating, and the impact of gravity. Our results also indicate how recently evolved multicellular organisms adapted the phototactic capabilities of their unicellular ancestors to multicellular life.
The ability of motile organisms to sense changes in external parameters is crucial in finding the best environmental conditions. These tactic responses were already developed in early single-celled life. When multicellular motile organisms evolved from unicellular life, previous achievements like tactic behavior had to be modified to fulfill the requirements of multicellularity [1-4]. The volvocine green algae, a group of species closely related to the "genus" Volvox within the order Volvocales (Chlorophyta), represent an excellent set of organisms for analyzing (photo)tactic responses during evolution of multicellularity [4-6]. This group of algae spans the full range of complexity from unicellular genera, such as Chlamydomonas, to colonial genera, such as Eudorina, to multicellular genera, such as Volvox .
Phylogenetic analyses indicate that multicellularity evolved much more recently in volvocine green algae than in any other group . Phylogenetic analyses of the order Volvocales also revealed a polyphyletic origin of the "genus" Volvox [5,8-13]. A few species of this genus, including Volvox rousseletii, form a small but robust monophyletic group, which is called the section Volvox [10,12,14-16]. All other species of the genus Volvox (with the exclusion of the section Volvox) and the genera Eudorina and Pleodorina constitute another, much larger monophyletic group, the Eudorina group [16,17] (see Additional File 1 for details).
All volvocine algae are flagellates that are dependent on phototactic behavior because they require sufficient light for photosynthesis and therefore need to orientate themselves in an efficient manner (for review, see ). For this, each (somatic) cell of each volvocine alga has two flagella for locomotion and an eyespot apparatus for light perception. The photoreceptors involved in the photoresponse have been identified both in Chlamydomonas reinhardtii [19-22] and Volvox carteri [23,24]. These photoreceptors are integral parts of a primordial visual system, forming, with the pigmented eyespot, a functional eye, which seems to share the same ultrastructure and physiology in both the unicellular Chlamydomonas and the multicellular Volvox [5,25-28].
In fact, the somatic cells of Volvox and its relatives are called "Chlamydomonas-like" in countless publications particularly due to the similarity of their eyes (and due to the presence of two flagella). Volvox, however, is much more than a multicellular version of Chlamydomonas. To allow for effective forward swimming and phototaxis, multicellular organization created two major requirements: (1) the appropriate arrangement and orientation of the biflagellated cells and (2) the coordination of cell behaviors.
Initially, a spherically symmetric arrangement and orientation of identical biflagellated cells might appear to be an ideal configuration for a multicellular organism. A hypothetical 5000-celled, spheroidal Chlamydomonas, however, would not be able to display any effective motility, not to mention phototaxis . Forward swimming would be impossible because each cell in such a spherical surface monolayer would have a counterpart on the opposite side of the spheroid with flagella pointing in the opposite direction, and therefore the flagellar forces generated by opposing cells would neutralize each other. Because Volvox is actually a spheroidal organism, questions arise as to how it actually swims forward and what is different from the swimming motion of Chlamydomonas. Although Chlamydomonas and Volvox swim forward and rotate simultaneously, they have to do it in a very different manner owing to their different geometries and complexities. Chlamydomonas swims toward the cellular anterior with a breaststroke-like motion and rotates counterclockwise (as viewed from behind the cell) about the cellular anterior-posterior axis [30-35]. It switches between nearly straight-ahead swimming with synchronous beating and abrupt large reorientations with asynchronous flagellar beating, which has been described as a eukaryotic version of the "run-and-tumble" motion of peritrichously flagellated bacteria . Because the Chlamydomonas cell rolls around its longitudinal cell axis during helical forward swimming, its eye receives a sinusoidally modulated light signal. In addition to phototaxis, Chlamydomonas also shows photophobic responses [34,35,37,38]. The photophobic response is caused by a switch in the flagellar waveform, whereas phototaxis is caused by changing the balance of beating between the two flagella [39-41].
In the spheroidal colonial and multicellular volvocine species, the cellular anterior-posterior axis is different from the anterior-posterior axis of the whole organism. The effective strokes of both flagella beat in the same or almost the same direction toward the posterior pole of the spheroid, and they beat in parallel planes pushing the spheroid in the posterior-anterior direction [42-44]. This type of beating is indispensable for the effective forward swimming of spheroidal colonial and multicellular flagellates; it evolved together with the transition from unicellularity to multicellularity and is caused by the rotation of the basal bodies that underlie the flagella and determine their orientations [6,8,42,45]. The net effective propulsion generated by the effective strokes is not directed exactly parallel to the posterior-anterior axis of the spheroid and therefore results in rotation during forward swimming [29,44,46]; this characteristic forward rolling motion is also reflected in the name of the Volvox genus (Latin for "fierce roller") . The arrangement, orientation, and beating direction of the biflagellated cells, however, explain only the reason that Volvox can swim forward but not its phototactic behavior.
For more than 100 years, scientists have studied the swimming behavior and phototaxis in multicellular (and colonial) volvocine algae (e.g., [29,46,48-61]). A key question in these studies on the phototactic behavior in multicellular volvocine algae was always how the coordination among their cells works. A cell-to-cell communication network among somatic cells that serves as the basis for the coordination of phototactic behavior seems to be rather obvious. Indeed, several species of the genus Volvox possess a network of cytoplasmic bridges even at the adult stage, which could allow for signal transduction between cells. However, amazingly, the multicellular volvocine algae are able to accomplish phototactic swimming without any known direct communication among cells [49,62,63]. This lack of communication becomes clear in species of the genus Volvox that lack any intercellular connections in adults (e.g., V. carteri); these species are well coordinated and swim toward the light, just as those with connections do. Likewise, individuals from species with cytoplasmic connections (e.g., V. globator) that had their connections microsurgically disrupted still showed phototactic behavior [49,62,63]. These observations bring up the question: How does the coordination of phototactic behavior work without direct communication among cells?
A change in the swimming direction in colonial and multicellular volvocine algae results from changes in the flagellar activity of cells in different portions of the spheroid. For V. aureus and V. carteri (both from the Eudorina group), fluid streamlines at the anterior pole were shown to stop transiently upon illumination, suggesting that cells at the anterior pole are responsible for the photoresponses [53-55,64]. Earlier, Fritsch  reported that cells at the anterior pole of the spheroid have larger eyespots than those at the posterior pole, which supported the idea of more sensitive eyes at the anterior pole [29,55]. Sakaguchi and colleagues [54,55] concluded that minor changes in the behavior of cells at the anterior pole (of V. carteri and V. aureus) that come into or out of an illumination beam path during the spheroid's swimming with rotation cause both positive and negative phototaxis.
Previously, two competing models for positive phototactic steering in Volvox had been proposed. In the "variable beat frequency model" [48,52-55] the cells at the anterior pole reduce their beat frequency as the light intensity changes as cells rotate from the shaded side to the one in the light. In addition, they increase their beat frequency as they rotate from the illuminated side to the one in the dark. In the "variable beat direction model" , the cells change their flagellar beat direction when the cells rotate from the shaded side to the one in the light and also when they rotate from the illuminated side to the one in the dark. On the dark side, the flagella beat along the anterior-posterior axis toward the posterior pole of the spheroid, whereas on the illuminated side, the flagella beat laterally. Hoops et al.  tested both models in V. carteri, and their results supported the variable beat frequency model while being inconsistent with the variable beat direction model for phototactic turning.
A recent mathematical theory and measurements in V. carteri suggest that colony rotation and photoresponsive kinetics have evolved to be mutually tuned and optimized for phototaxis .
In the present study, the phototactic behavior in the spheroidal, multicellular volvocine green alga V. rousseletii (section Volvox), one of the fastest swimmers among all volvocine green algae, was analyzed to address the question of how a multicellular organism accomplishes phototactic swimming without any known direct communication among cells. To our knowledge, this is the first detailed description of phototactic behavior in a species within the section Volvox.
In response to light stimuli, not only was the beat frequency in cells on the anterior hemisphere changed, but also the beat direction was reversed. Moreover, the flagella waveform changed when the cells reversed the beat direction in response to changes in light intensity. The pulsed illumination of somatic cells at the anterior pole demonstrated that V. rousseletii quickly responds to changing light conditions with a reversal of the beating direction. We show that positive phototaxis is assisted by gravitational forces and that there is no negative phototaxis in V. rousseletii (under our experimental conditions). Finally, we present a model for positive phototactic steering in Volvox rousseletii that is consistent with both our results and those of previously published studies.
The wild-type Volvox rousseletii strain MI01 was isolated in 1998 from the Machi-ike pond in Oh-gata, Tsukuba-shi, Ibaraki, Japan. A phylogenetic analysis of this strain was made to confirm its identity, place it accurately within the phylogenetic tree, and confirm that it belongs to the section Volvox. The analysis was based on cDNA fragments of chloroplast genes (psaA, psaB and rbcL) and an internal transcribed spacer sequence (ITS2) from 47 volvocine species [11,16,17,66-70]. The background and procedures of the phylogenetic analysis are described in Additional File 2. Detailed information for the cDNA sequences (e.g., source species and/or strains, abbreviations, accession numbers and references) is described in Additional File 3. The alignments that were performed are shown in Additional Files 4, 5 and 6, and the sequence identity calculations are described in Additional Files 7, 8, 9 and 10. A consensus tree based on 30,000 resampled data sets for the psaA, psaB and rbcL cDNA fragments (10,000 data sets from each) is shown in Additional File 1, together with some phylogenetic commentary. The phylogenetic tree indicates polyphyly of the genus Volvox, which is consistent with several previous studies [10,12,16,17]. The species V. barberi, V. globator and V. rousseletii appear on the same branch, which corresponds to the monophyletic section Volvox [5,14,16,17]. The species used in this study, Volvox rousseletii strain MI01, appears next to the Volvox rousseletii UTEX 1862 strain.
An adult V. rousseletii alga consists of a spherical surface monolayer of ~5000 small biflagellate, terminally differentiated somatic cells and 1-20 asexual reproductive cells (the number greatly depends on environmental conditions). The cells are regularly positioned in a transparent spheroid of a glycoprotein-rich extracellular matrix, and this spheroid displays a distinctive morphological polarity along its anterior-posterior axis. The whole organism view shows that the spheroid is somewhat more enlarged along the anterior-posterior axis than along the equatorial axis (Figure (Figure1c).1c). In embryogenesis, mature asexual reproductive cells, which are located in the posterior hemisphere, undergo embryonic cleavage divisions, with the characteristic cleavage pattern of the embryo establishing the polarity of the organism. The fully cleaved embryo is inside out and must turn right side out in a gastrulation-like process called inversion . Next, the juvenile spheroids within the adult increase in size by depositing large quantities of extracellular matrix and finally hatch from their parent. The juvenile spheroids are always located within the posterior hemisphere due to the position of the original reproductive cells (Figure (Figure1c).1c). The juvenile spheroids cause the posterior hemisphere to be denser than the anterior hemisphere [71,72], with a likely contribution by the closer spacing of somatic cells on the posterior hemisphere (see next paragraph). This anisotropic mass distribution ensures that the spheroids always sink with their posterior pole first.
Only volvocine algae in the section Volvox, to which V. rousseletii belongs, retain robust cytoplasmic bridges even in the adult [5,14]. An extensive network of these characteristic cytoplasmic bridges makes the somatic cells appear stellate when viewed from their flagellar ends (Figs. (Figs.1a,1a, 1 to 4, and and1b,1b, 1 to 4) and bell-shaped when viewed from the side (shown schematically in Figs. Figs.2i2i to to2l).2l). The somatic cells at the anterior pole are larger than those at the posterior pole, and the cell-to-cell distances at the anterior pole are also larger (Figure 1, a1 and 1, b1). Owing to the transparent extracellular matrix, the outer edge of each somatic cell is indistinct; therefore, we measured the protoplast surface areas and distances between protoplasts. When compared with the posterior pole, the protoplast surface areas and the distances between protoplasts at the anterior pole were 1.8-fold larger (Figure (Figure1f)1f) and 2.3-fold longer (Figure (Figure1g),1g), respectively. The decrease in cell distances along the anterior-posterior axis also becomes apparent in the view of the whole spheroid (Figure (Figure1c),1c), and as mentioned above, this closer spacing of somatic cells on the posterior hemisphere might contribute to the higher density of the posterior hemisphere. The somatic cells at the anterior pole have large eyespots (~3.6-μm diameter) that face toward the posterior pole (Figure (Figure1a,1a, 1 to 4). The diameter of the eyespots decreased continuously along the anterior-posterior axis (Figure (Figure1d).1d). Cells at the posterior pole have either a tiny or an undetectable eyespot. Those eyespots that are present do not face in the same direction (Figure (Figure1b,1b, 1 to 4). A comparison of the eyespot surface areas of cells at the anterior pole with those at the posterior pole highlights these differences in eyespot size; the surface areas at the anterior pole are ~80-fold larger than those at the posterior pole (Figure (Figure1e),1e), indicating that the cells at the anterior pole possess the highest light sensitivity and that the sensitivity decreases continuously along the anterior-posterior axis toward the posterior pole. The cells at the posterior pole are light-insensitive and essentially blind.
The phototactic movements of the V. rousseletii spheroids were analyzed in vertical (setup A, Figure Figure3a)3a) and horizontal directions (setup B, Figure Figure3b)3b) under continuous unidirectional illumination with a broad range of intensities spanning approximately eight orders of magnitude (Figure (Figure3c).3c). For the calculation of the photoaccumulation index (PI), the observation chamber was divided into six (setup A) or three (setup B) areas, with area 1 closest to the light source.
An example of the calculation of the PI for all areas at 0.16 μmol m-2 s-1 in setup A is shown in Figure Figure3d.3d. When the light is on, the PI for area 1 remains relatively constant for ~5 s and then increases continuously. The initial delay is caused by a reduction in swimming speed after the dark-light switch (see below sections "Swimming speed after a dark-light switch as a function of light intensity" and "Swimming speed after light stimulation as a function of the swimming direction"). The PI for area 1 reaches its maximum after ~25 s, whereas the PI of the other areas decreases in return. The PI for area 2 increased temporarily because the spheroids have to cross this area to reach area 1. In Figures Figures3e3e to to3h,3h, only the results for area 1 are shown because they sufficiently describe the photoaccumulation.
In the vertical setup A, light intensities of 0.016 μmol m-2 s-1 or above resulted in the same phototactic behavior as described above (Figure (Figure3e3e and and3f).3f). Remarkably, high light intensities of up to 457 μmol m-2 s-1 also yielded strong positive phototaxis, with the spheroids accumulating in area 1 within ~25 s. Even very low light intensities (0.00016 μmol m-2 s-1) resulted in a small increase of the PI. The photoaccumulation in the horizontal setup B (Figure (Figure3g3g and and3h)3h) was essentially the same as in the vertical setup. In contrast, very low light intensities (i.e., 0.0016 μmol m-2 s-1 or below) had no significant effect. The lower sensitivity at low light intensities in setup B compared with setup A seemed to be caused by the facilitating effects of gravity on phototaxis (see sections "Swimming speed after light stimulation as a function of the swimming direction" and "Gravity facilitates positive phototaxis" in the Discussion), which might not be observed in setup B due to the dimensions of the observation chamber combined with the direction of the light vector. At light intensities between 0.005 and 0.16 μmol m-2 s-1, the PIs at 10, 20, or 30 s after the light is switched on increase with increasing light intensity (Figure (Figure3h),3h), such that the higher the intensity, the earlier the spheroids reach the light source. There is no further increase in PI at intensities above 0.16 μmol m-2 s-1 (Figure (Figure3h).3h). As in setup A, even the high light intensities (up to 520 μmol m-2 s-1) produce a strong positive phototaxis. These results indicate that there is no negative phototaxis in V. rousseletii (under the conditions of this study).
To determine whether the length of the dark period before the light stimulus influences the phototactic movements, light-adapted spheroids were kept in the dark for 0 to 90 min and subsequently subjected to a photoaccumulation assay (Table (Table1).1). These results demonstrated that longer dark periods reduced the efficiency of the phototactic movements, decreasing continuously from 100% to ~65% within an hour in the dark. Periods of darkness longer than 1 hour, however, did not result in any further decrease of significance.
To determine the swimming speed of individual spheroids after a dark-light switch, the tracks of the spheroids were recorded as shown in Figure Figure4a.4a. The speed of individual spheroids was determined at 1-s intervals from 1 s before to 4 s after the dark-light switch. Eight different light intensities, spanning approximately eight orders of magnitude, were analyzed separately, and the relative swimming speed of the spheroids was plotted against the time after the light was turned on (Figure (Figure4b).4b). A dark-light switch using low light intensities (i.e., between 0.00016 and 0.016 μmol m-2 s-1) caused a speed reduction to ~70% relative to the swimming speed immediately before light stimulation. Higher light intensities (i.e., between 0.16 and 457 μmol m-2 s-1) caused a speed reduction to 35% to 45% (Figure (Figure4b).4b). These speed reductions occurred within 1 s of the onset of illumination, and the former speed before the onset of darkness was recovered in ~3 to 4 s. This temporary speed reduction reflects a brief photophobic response of the organism. Overall, the results with all intensities indicate that the higher the light intensity, the stronger the speed reduction.
The absolute swimming speed of recently hatched spheroids in the dark (setup A, Figure Figure3a)3a) was determined to be ~880 μm s-1 (SD 270 μm s-1, n = 50) in an upward direction and 1060 μm s-1 (SD 440 μm s-1, n = 50) in a horizontal direction. In contrast, Solari and coworkers [73,74] reported an upward swimming speed of ~500 μm s-1 (up to ~590 μm s-1) for V. rousseletii. These differences may be due to different culture conditions and a different experimental setup, particularly with respect to the dimensions of the observation chamber. In our experiments, the spheroids were only able to swim along the x- and y-axes but not the z-axis, which extended only 0.1 cm. Solari et al. used a chamber that extended 1 cm along the z-axis, allowing movements along this axis that may account for the lower values for the upward swimming speed (y-axis).
To investigate the swimming speed of individual spheroids after a dark-light switch relative to the swimming direction just before the light (2.1 μmol m-2 s-1) was turned on, setup A (Figure (Figure3a)3a) was used, and the spheroids were tracked as described above (Figure (Figure4a).4a). In each track, a line between the spheroid's position 1 s before the dark-light switch and its position right at the dark-light switch was drawn. The angle between each of these lines and the direction of the light vector was determined, and the angles were assigned to sectors a-i (see legend in Figure Figure5a).5a). The speed of each spheroid was determined at 1-s intervals from 1 s before to 4 s after the onset of illumination. For each swimming direction in the dark (a-i), the relative swimming speed of the spheroids was plotted against the time after the onset of illumination (Figure (Figure5a).5a). The dark-light switch caused a speed reduction, regardless of the directions in which the spheroids were swimming immediately before the dark-light switch. This result is even true for direction a, in which the spheroids had already swum to the light source by chance as the light was turned on. There were, however, sector-dependent differences in speed reduction. For sectors a-c, speed was reduced to ~30% to 45% compared with the swimming speed immediately before light stimulation, and for sectors d to i, it was reduced to ~50% to 60% (Figure (Figure5a).5a). These sector-dependent differences become even clearer when the absolute swimming speeds are represented in a sector-wise manner (Figure (Figure5b).5b). There is already a sector dependency of the absolute swimming speed before the onset of illumination (0 s, Figure Figure5b),5b), indicating that spheroids swim ~1.5 times faster to the bottom than to the top. This sector-dependency remained when the light was switched on, and the absolute speed was promptly reduced (1 s, Figure Figure5b).5b). Interestingly, the sector dependency persists when the spheroids accelerate to their previous speed (2-4 s, Figure Figure5b).5b). Consequently, the deceleration and acceleration of spheroids after a dark-light switch is independent from the swimming direction relative to the light source immediately before the onset of illumination, but it is influenced by gravitational force.
The analysis of the course of the tracks also made the impact of gravity apparent. Tracks from vertical setup A (Figure (Figure3a)3a) showed that the immediate speed reduction after the dark-light switch was accompanied by a change in the moving direction toward the bottom (Figure (Figure5c).5c). This sinking takes ~2 s, and the spheroids drop by ~0.45 mm (SD 0.15 mm, n = 20) before they accelerate and swim to the light source. This temporary sinking is indicative of the brief photophobic response of the organism after the dark-light switch. Tracks from horizontal setup B (Figure (Figure3b)3b) also show an immediate speed reduction after the dark-light switch with subsequent acceleration as the spheroids swim to the light source (Figure (Figure5d).5d). Owing to the dimensions of the observation chamber (0.1 cm in the vertical direction) and the viewing direction (antiparallel to the gravitational force), the sinking characteristic is not seen in the horizontal setup B (Figure (Figure5d5d).
Visualization of fluid streamlines in a suspension of polystyrene beads  allowed the analysis of flagellar activity of V. rousseletii spheroids before and after a dark-light switch (Figure (Figure6).6). In the dark, organisms that were gently trapped between a cover glass and a glass slide produced fluid streamlines in the anterior-posterior direction along the surface of the spheroid (Figures (Figures6a6a and and6d).6d). These streams resulted in forward swimming along the posterior-anterior axis in free-swimming spheroids. Exposure of the spheroids to illumination (2.1 μmol m-2 s-1) caused a transient stop of the streams in front of the spheroid and a reversal of the fluid streamlines along the anterior hemisphere. In contrast, the fluid streamlines along the posterior hemisphere showed no significant change (Figure (Figure6b).6b). The particle velocities along the anterior hemisphere were lower in the reversed direction (Figure (Figure6e)6e) than in the anterior-posterior direction in the dark (Figure (Figure6d).6d). The reversal of the fluid streamlines indicates a reversed beating direction of flagella because the streamline pattern cannot be explained by a simple stop of flagellar beating as has been observed in V. carteri [54,55]. The reversal of the fluid streamlines lasts for 2 to 3 seconds immediately after the dark-light switch. The initial anterior-posterior fluid streamlines are then reestablished.
These results are consistent with the speed reduction and sinking of the spheroids after a dark-light switch described above and support the existence of a photoresponsive gradient from the anterior to the posterior pole of the spheroid, with the highest responses at the anterior and no response at the posterior.
Direct observation of flagellar activity by dark-field microscopy allowed an analysis of the cellular basis of the reversal of the fluid streamlines (Figures 2a-f). The flagellar activity was recorded 1 s before and 1 s after light stimulation with an exposure time of 0.004 s (Figure (Figure2a).2a). In the dark, the flagella of all somatic cells beat with a ciliary-type, asymmetrical motion, which we refer to as the normal beating mode (Figures (Figures2b2b and and2e).2e). This mode consists of an effective stroke in the anterior-posterior direction and a recovery stroke in the opposite direction. After the light stimulus, the cells within the anterior hemisphere completely reverse the flagellar beating direction, which we refer to as the reverse beating mode (Figures (Figures2c2c and and2f).2f). Though the effective stroke is then in the posterior to anterior direction, the cells still beat with a ciliary-type motion. The reverse beating mode of cells on the anterior hemisphere lasts for 2 to 3 seconds, after which the cells switch back to the normal beating mode with the flagellar strokes and waveforms before light stimulation are completely identical to those 2 to 3 seconds after light stimulation. This result is consistent with the observed fluid streamlines after a dark-light switch as described above. The temporary reversal of the beating direction reflects a brief photophobic response at the cellular level.
High-speed microvideography was used to examine the flagellar strokes and waveforms of individual somatic cells more closely. Frames from the captured high-speed videos of a somatic cell on the anterior hemisphere show the normal beating mode (in the dark; Figure Figure2g)2g) and the reverse beating mode (0.1 s after light stimulation; Figure Figure2h).2h). The superimposed flagellar waveforms show the complete stroke cycles of one flagellum in the normal (Figure (Figure2i)2i) and the reverse (Figure (Figure2j)2j) beating modes. The reverse beating mode is only transient, with the somatic cells returning to their normal beating mode after adaptation to the light, which occurs after approximately 2 to 3 seconds. Cells in the normal beating mode show a typical base-to-tip, ciliary-type motion. The stroke area has a wide spread, and the tip of the flagellum describes a relatively wide arc during its effective stroke (Figure (Figure2i).2i). One stroke takes ~45 ms (frequency 22 Hz [SD 6 Hz, n = 15]) in the normal beating mode. In the reverse beating mode, one stroke takes ~25 ms (frequency 40 Hz [SD 9 Hz, n = 15]), and the cells also show a ciliary-type motion. There is, however, less bending close to the base of the flagellum and a much smaller stroke area, such that the tip of the flagellum describes only a small arc during its effective stroke (Figure (Figure2j2j).
The description of flagellar waveforms requires that the angle of view be essentially perpendicular to the bending plane of the flagella. From this angle of view, only the beat of one flagellum, the one closest to the observer's eye, can be described properly. To observe both flagella of a cell at the same time, the angle of view was changed so that it was almost parallel to the bending plane of the flagella (Figures (Figures2k2k and and2l).2l). The beating direction of the two flagella of a somatic cell is roughly parallel, and the effective strokes are generally directed toward the posterior pole. There is no evidence for any spatial or temporal coordination between the two flagellar beat cycles of a somatic cell, which is indicative of the asymmetrical, ciliary-type beating or between the beat cycles of the neighboring somatic cells. An example of the strokes of a single somatic cell in the normal beating mode is shown in Figures Figures2k2k and and2l.2l. The strokes of the two flagella shown in Figure Figure2l2l were recorded only 0.13 s after the strokes in Figure Figure2k2k without any changes in light or other conditions. A comparison of these strokes not only illustrates the asynchronous and asymmetrical beating of the flagella but also documents the three-dimensional component of the strokes. Beat cycles that were somewhat out of the normal bending plane were repeatedly observed, which may be a matter of slightly variable fluid resistance due to microturbulences caused by flagella from other cells.
A Volvox rousseletii spheroid always swims along its posterior-anterior axis while rotating about its posterior-anterior axis in a counterclockwise direction (as viewed from behind the spheroid). Spheroids make one complete counterclockwise rotation approximately every 1 to 3 seconds (Figure (Figure7a),7a), with smaller (younger) spheroids rotating faster than larger (older) spheroids. The eyespots of somatic cells are highly directional optical devices that guide the organism to places where the light conditions are optimal for photosynthetic growth. The light signals change periodically during phototactic swimming due to the rotation of the spheroid and the directivity of the eyespot with its layers of carotenoid-filled granules below the photoreceptors in the plasma membrane  (Figure (Figure7c).7c). The periodically changing light signals of a rotating spheroid during phototaxis were simulated using a rotating filter system (Figure (Figure7b),7b), and fluid streamlines from three regions at the anterior pole were analyzed (Figure (Figure7a).7a). The construction of the rotating filter system was based on previous results on the directivity of photoreception in the unicellular alga Chlamydomonas  (Figures (Figures7d7d and and7e),7e), which corresponds to the situation in somatic cells on the anterior hemisphere of a Volvox spheroid (Figure (Figure7d,7d, blue line) as viewed from the flagellar end of the cells (Figure (Figure7d,7d, inset). The filter combinations and cutting of the filters were calculated to match the plot of the tangential electric energy density  at the plasma membrane overlaying the carotenoid-filled granules of the eyespot (Figure (Figure7e),7e), and the rotating filter system was constructed using the parameters given in Figure Figure7b.7b. Our simulation of a spheroid swimming with rotation matches the in vivo situation in somatic cells very well (Figure (Figure7d,7d, red line). Spheroids were gently trapped between a coverglass and a glass slide, and fluid streamlines were visualized using polystyrene beads. After a dark-light switch, the light intensity was changed periodically (1.2-s intervals) with peaks in the intensity. The relative length of the tracks of polystyrene beads decreased sharply within ~300 ms after the dark-light switch (Figures 7f-h), and this period of minimal bead movement persisted for ~2.5 s, even though two peaks in light intensity occurred during this time (Figure (Figure7i).7i). These peaks only caused a few changes in the length of the tracks in regions 1 and 2 (Figures (Figures7f7f and and7g).7g). After this delayed reaction, which is consistent with the speed reduction and sinking of spheroids after a dark-light switch described above, the relative length of the bead tracks in all analyzed regions at the anterior pole changed with the same frequency as the fluctuations in the light intensity (Figures 7f-i). The minimal length of the tracks lagged behind the peaks in light intensity by ~300 ms. Interestingly, when the light was turned off after the periodical light pulses, the relative length of the bead tracks persisted at the maximal level (Figures 7f-i). Although the bead tracks were generally longer in region 2 (Figure (Figure7a7a and and7g),7g), which is closer to the spheroid than regions 1 and 3, the results from all three regions were quite similar.
The reaction time of somatic cells at the anterior pole was calculated from high-speed microvideographs after a dark-light switch (Figures (Figures2g2g and and2h)2h) and from dark-field microscopy with pulsed illumination (Figure (Figure7).7). High-speed microvideography demonstrated that the flagella begin to reverse the beating direction after a dark-light switch after ~100 ms (SD 25 ms, n = 5). The transition from the normal beating mode to the reverse beating mode takes ~30 ms (SD 10 ms, n = 5). Thus, the period of time spanning the start of the light stimulation to the completion of the reversed beating direction is ~100 to 160 ms. In the above experiments with periodically changing light intensities, the minimum of the fluid streamlines lagged behind the peaks in light intensity by ~300 ms (Figures 7f-i). Owing to the reaction time of ~100 to 160 ms, the reversed flagella need ~140 to 200 ms for their fluid streamlines to reach their minimum.
In this study, we investigated key parameters of phototactic behavior in the spheroidal, multicellular volvocine green alga Volvox rousseletii, one of the fastest swimmers among all volvocine green algae. This is the first detailed description of phototactic behavior in a species within the Volvocales section Volvox.
The reversal of the ciliary-type beating of the flagella shown in this study (Figure (Figure2)2) has not yet been observed in other plants or green algae, but it has been reported for ciliates [76,77] and some metazoa [78,79]. In particular, the ciliate Paramecium caudatum has been widely known for its avoidance reaction, which is a sudden change in the swimming direction of the cell mediated by a transient reversal of its ciliary activity . In Paramecium, the orientation of ciliary beating is controlled by the concentration of intracellular calcium [81-84]. Calcium is also well known for its role in the light-dependent responses of the unicellular Chlamydomonas, the best-studied volvocine alga with respect to flagellar activity and photoresponses [30,39,40,58,85-97]. The molecular mechanisms of light perception signal transduction and the control of flagellar beating identified in Chlamydomonas most likely are not specific to this species and instead are quite similar in all volvocine algae, given their close phylogenetic relationships. There are significant differences, however, in the mode of flagellar beating within the volvocine algae. Although the normal beating mode is a ciliary-type, asymmetrical motion, the light-induced flagellar beating pattern varies. Chlamydomonas responds with a flagellar-type, symmetrical beating, Volvox aureus  and V. carteri  respond with a cessation of flagellar beating, and V. rousseletii responds with a ciliary-type, asymmetrical beating in a reversed direction (Figure (Figure2).2). These striking differences within the genus Volvox probably substantiate the polyphyletic origin of this genus. Phylogenetically, V. aureus and V. carteri belong to clade A within the Eudorina group [16,17], whereas V. rousseletii belongs to section Volvox [10,12,14-16] (see Additional File 1). Therefore, the light-induced ciliary-type, asymmetrical beating in a reversed direction might be characteristic of those species belonging to the section Volvox. The reversal of the beating direction in light-induced cells should allow for faster changes in the swimming direction of the organism and better maneuverability compared with a simple cessation of flagellar beating in light-induced cells. Thus, V. rousseletii should outperform V. aureus and V. carteri in phototaxis merely because of its enhanced steering ability, not to mention its faster swimming speed. This assumption still requires experimental verification.
In addition to the flagellar forces, gravitational forces participate in phototaxis. Whenever a V. rousseletii spheroid slows down or stops swimming, gravity causes the spheroid to sink toward the bottom with its posterior pole first (see sections "Polarity of the V. rousseletii spheroid" and "Swimming speed after light stimulation as a function of the swimming direction" and Figure Figure5c).5c). Even during normal swimming, gravity pulls on the posterior hemisphere more as a result of an anisotropic mass distribution caused by the denser daughter spheroids and probably by the closer spacing of somatic cells within the posterior hemisphere. This gravity effect has been quantitatively measured through biophysics in other species of the genus Volvox, which was referred to as "bottom-heaviness" [71,72]. Thus, through gravity, the posterior-anterior axis tends to become oriented in the opposite direction of the gravity vector such that the anterior pole tends to be on top. In the natural habitat, the sun, which serves as the light source, essentially shines from above, resulting in the direction of the light vector being roughly the same as that of the gravity vector. Therefore, gravity facilitates positive phototaxis because it brings the spheroids into the optimal orientation to swim toward the light source.
Even in the unicellular relative Chlamydomonas, cells with immobilized flagella sediment with their anterior ends pointing up [98,99] because the posterior chloroplast-containing part of the cell body is denser than the anterior flagella-bearing part .
Thus, the utilization of gravity to ensure that the anterior end is always oriented toward the top while sinking seems to be a clear evolutionary advantage for all of the phototrophic and positively phototactic volvocine algae.
In several earlier publications, observations in connection with phototaxis were combined to get an overall picture of how phototaxis works in Volvox. These descriptions and models of the swimming behavior in Volvox refer to the cells at the anterior hemisphere of the spheroid as being a crucial factor in phototactic steering and in its rotation during forward swimming to bring certain cells into or out of the light [46,50,52-55,101]. There had been different explanations as to how the individual cells on the anterior hemisphere change their flagellar activity in response to different light stimuli. Thus, the two above-mentioned competing models emerged, which were the variable beat frequency model [48,52-55,57] and the variable beat direction model . A more recent report analyzed both models and suggested the variable beat frequency model was the best description of phototactic turning in Volvox carteri . This model is supported by the decrease of both the rate of progression and the rotation of V. carteri spheroids in the presence of illumination . In addition, the fluid streamlines near the anterior pole of V. carteri  and V. aureus [52-54] spheroids stopped upon illumination. The researchers, however, did not monitor flagellar beating directly but drew conclusions from the behavior of those spheroids exposed to light stimuli. In 2006, Nozaki et al.  assigned the phylogenetic position of the species V. carteri and V. aureus to clade A in the Eudorina group (see Additional File 1).
The variable beat direction model  is supported by the following quite contrary, indirect observation: Mast  determined that the rate of progression of an unidentified species of the genus Volvox decreased after illumination while its rate of rotation increased. Mast's drawings and descriptions, however, indicated that the observed Volvox species belonged to the section Volvox . Hoops et al.  tried but unfortunately could not replicate the step-up and step-down illumination experiments with Volvox rousseletii and Volvox capensis, both of which belong to the section Volvox. Therefore, Hoops et al.  concluded that a (re-)analysis of phototactic steering in the spheroids of the section Volvox is important.
The phylogenetic differences between the investigated species may indicate that there are differences in phototactic mechanisms that originally led to the two different models. Because the above models are based on experiments that do not include direct observations of flagella due to the small size and rapid movement of the flagella, the significance of these models may be limited.
On the basis of the above and our own observations, we developed a mechanistic model that predicts the phototactic behavior in V. rousseletii. At the organismal level, we have shown that V. rousseletii spheroids respond to a sudden change in light intensity with a momentary photophobic response, reducing their speed rapidly for ~2 s and causing a gravitational sinking of the spheroids (Figures (Figures4b4b and and5).5). They then accelerate quickly and obtain their original swimming speed while turning phototactically toward the light source (Figure (Figure5).5). In this response, not all flagellated somatic cells of the spheroid participate in the same way. There is a photoresponsive gradient from anterior to posterior, with the highest light sensitivity at the anterior pole of the spheroid and no response to light at the posterior pole (Figure (Figure6).6). This gradient is reflected by an eyespot gradient in which the cells with the largest and most light-sensitive eyespots are located at the anterior pole and the cells with the smallest, even nonexistent, and blind eyespots are located at the posterior pole (Figure (Figure1).1). After a change in light intensity, only cells in the anterior hemisphere with an adequately sized eyespot perceive the change in light intensity and switch transiently from the normal beating mode to a reverse beating mode (Figure (Figure2),2), which is reflected by a momentary photophobic response at the cell level. The switch in the beating direction generates a force in the opposite direction on the anterior hemisphere, while cells on the posterior hemisphere still beat in the normal beating mode, causing a deceleration of the spheroid. The subsequent acceleration and phototactic turn toward the light source is complicated by the rotation of the spheroids in a counterclockwise direction as they swim along their posterior-anterior axis (Figure (Figure7a).7a). In addition, the eyes of the somatic cells show a strong directivity (Figure (Figure7d).7d). Because the flagellar reaction cannot be observed in free swimming and rotating spheroids, the situation was simulated by holding the spheroid in place while the illumination was changed periodically (Figures 7f-i). Thus, the individual somatic cells of the anterior hemisphere are in the same situation as the corresponding somatic cells of a free swimming, rotating spheroid, which is illuminated on the side. The somatic cells of the anterior hemisphere respond quickly and periodically by reversing the direction of the flagellar beat (Figs. (Figs.22 and and7).7). In a free swimming, rotating spheroid, the local reversal of the beating direction causes an unbalanced force between the illuminated and the shaded side of the spheroid. As a result, the spheroid turns toward the light source. This mechanism does not require any communication between the cells because the flagellar responses of the somatic cells are coordinated only via the environmental factors of the position of the light source combined with the effects of gravity.
One final point that should be mentioned is that while each individual somatic cell has a forward and a reverse gear (Figure (Figure2),2), the whole organism only has a forward gear, such that it can only swim in a posterior to anterior direction (Figure (Figure6)6) but can turn easily.
The main components of our model of phototactic movements in V. rousseletii are illustrated in Figure Figure8,8, and the following conclusions summarize the relevant aspects.
On the basis of all results presented herein, we developed a mechanistic model that predicts phototactic behavior in Volvox rousseletii and shows how this multicellular organism achieves coordination among its individual biflagellated cells without direct communication between these cells.
The model encompasses the 10 following points:
1. The V. rousseletii spheroids (under the conditions of this study) show only positive phototaxis but not negative phototaxis, even at high light intensities (Figure (Figure33).
2. Spheroids swim along the posterior-anterior axis and simultaneously rotate about this axis in a counterclockwise direction, with one turn every 1 to 3 seconds (Figure (Figure7a7a).
3. The spheroid has a distinctive morphological polarity along the anterior-posterior axis, with only the somatic cells at the anterior pole having large eyespots (~3.6-μm diameter) and a continuous decrease in the eyespot size toward the posterior pole (Figure (Figure11).
4. The spheroids show a strong photoresponse gradient from the anterior to the posterior pole, and only cells in the anterior hemisphere show an effective light response (Figure (Figure66).
5. In response to light stimuli, the somatic cells of the anterior hemisphere can reverse and recover their flagellar beating mode quickly, within ~100-160 ms (Figure (Figure22).
6. The flagella show a ciliary-type, asymmetrical beating in both directions, but the flagella waveform and beat frequencies are different (Figure (Figure22).
7. Gravity facilitates positive phototaxis due to the anisotropic mass distribution with the posterior of the spheroid being heavier than the anterior that results in the anterior, which contains the larger eyespots, always facing the top, where the light source normally is located (Figures 8a-c).
8. A sudden increase in light intensity causes the somatic cells of the anterior hemisphere to show a photophobic reaction for ~2 s, with an accompanying transient reversal of the ciliary activity (Figures (Figures2c2c and and2h;2h; Figure Figure6b),6b), causing a deceleration and sinking of the spheroid (Figures (Figures4,4, ,5,5, and and8b8b).
9. During phototactic swimming, only somatic cells of the anterior hemisphere with eyespots pointing toward the light source reverse the beating direction in the presence of illumination, resulting in a turn toward the light source (Figures (Figures2,2, ,6,6, ,7,7, and and8c8c).
10. The coordination of the spheroid's individual biflagellated cells during phototactic swimming occurs via environmental factors (e.g., the position of the light source and the effects of gravity) without any direct communication between the cells.
On the basis of our model of phototactic movements of the multicellular alga V. rousseletii, and taking into account previous considerations by Hoops  and Kirk , we conclude that the following evolutionary innovations were required to allow for phototactic movements after the transition from a unicellular Chlamydomonas-like ancestor to the multicellular V. rousseletii:
1. Both flagella of all cells must beat in essentially the same direction rather than the previously used breaststroke.
2. An extracellular matrix must hold all cells of the multicellular organism in the appropriate places on the surface of a spheroid.
3. The multicellular organism must not consist of identical cells and requires a distinctive morphological polarity, the flagella of all cells must beat toward the posterior, and the anterior cells must show a stronger light sensitivity, mediated through larger eyespots, than posterior cells.
4. The flagellar beating must cause rotation of the spheroid instead of rotation of the cell.
5. Light stimuli must cause a transient ciliary-type, asymmetrical beating in the reverse direction instead of a flagellar-type, symmetrical beating.
More work is clearly necessary, however, to confirm these evolutionary considerations.
The wild type Volvox rousseletii strain MI01 was grown in VT [102,103] or VTAC [104,105] medium at 20°C in a 10 h dark/14 h cycle under cool fluorescent white light at an average of 30-40 μmol photons m-2 s-1 of photosynthetically active radiation.
An observation chamber with internal dimensions of 10 × 10 × 1 mm was constructed as follows: (1) an acrylic cuvette (Sarstedt, Nümbrecht, Germany) was cut into slices with a 1-mm thickness, (2) a slice of the cuvette was glued onto a standard glass slide, and (3) the chamber was filled with a suspension of algae and covered with a coverglass, which was held in place by the adhesion force of water. The observation chamber contained 20-60 spheroids when it was used in the vertical orientation (Figure (Figure3a)3a) and 50-80 spheroids when in the horizontal orientation (Figure (Figure3b).3b). For observation in the vertical orientation (Figure (Figure3a),3a), the chamber was mounted upright on a stand and illuminated with a slide projector (Master Auto Lux-H; Rikagaku Seiki, Tokyo, Japan), and the movement of spheroids was recorded with a charge-coupled device (CCD) camera (XC-77; Sony, Tokyo, Japan) equipped with a C-mount macroscopic lens (Cine-Nikkor 1: 1.8, f = 25 mm; Nikon, Tokyo, Japan). For observation in the horizontal orientation (Figure (Figure3b),3b), the observation chamber was monitored using the CCD camera (XC-77; Sony) on a standard inverted microscope (TMS-F; Nikon). A phototactically neutral field illumination was achieved with a long-pass filter (λT >750 nm, LX902 AcryFilter IR; Mitsubishi Rayon, Tokyo, Japan), which lets infrared light through but filters out all visible light. For the analysis of photomovement, the observation chamber was illuminated from the direction that was being tested (Figures (Figures3a3a and and3b)3b) using a continuous-output 500-W Xenon short-arc lamp (Ushio Electric, Tokyo, Japan) equipped with an interference filter for microscopic phase contrast illumination (GIF, λT (max): 540 nm, spectral width [full width at half maximum]: 41 nm; Nikon), which results in green light.
The influence of light intensity on photomovements was analyzed using the 500-W Xenon short-arc lamp and a set of neutral density (ND) filters (ND1, ND3, ND10, ND20, and ND40; Hoya Corporation, Tokyo, Japan). Eight different light intensities (0.00017 μmol m-2 s-1, 0.0017 μmol m-2 s-1, 0.017 μmol m-2 s-1, 0.16 μmol m-2 s-1, 2.18 μmol m-2 s-1, 19.59 μmol m-2 s-1, 191 μmol m-2 s-1 and 457 μmol m-2 s-1) were used in the experiments with the vertically oriented observation chamber, and 17 different light intensities (0.00052 μmol m-2 s-1, 0.00156 μmol m-2 s-1, 0.0052 μmol m-2 s-1, 0.0156 μmol m-2 s-1,0.052 μmol m-2 s-1, 0.156 μmol m-2 s-1, 0.52 μmol m-2 s-1, 1.04 μmol m-2 s-1, 1.56 μmol m-2 s-1, 2.08 μmol m-2 s-1, 5.2 μmol m-2 s-1, 10.4 μmol m-2 s-1, 15.6 μmol m-2 s-1, 20.8 μmol m-2 s-1, 52 μmol m-2 s-1, 208 μmol m-2 s-1 and 520 μmol m-2 s-1) were used in the experiments with the horizontally oriented observation chamber.
Phototactic movements were quantified by calculating the PI using the formula PI = (B - A) × 100/(100 - A), in which A is the percentage of spheroids located in the investigated area (e.g., area 1) at the moment when the light was turned on (0 s) and B is the percentage of spheroids located in the same area at the respective time after the light was turned on. A high PI reflects a strong photoaccumulation within the given area.
Where applicable, individual images of recorded photomovements were analyzed with respect to the relative distribution of the spheroids in the chamber, the direction of the movements and the velocity of the movements using the NIH Image version 1.62 software .
The fluid streamlines generated by flagella were visualized and recorded according to the method of Hand and Haupt , with minor modifications. Briefly, ~40 μl of a suspension of individual Volvox spheroids in VT medium was pipetted onto a glass slide, and then 1-5 μl of an aqueous suspension of polystyrene beads (1-μm diameter; Polysciences, Warrington, PA, USA) were added. Two layers of standard vinyl tape were used as spacers between the slide and the coverglass to avoid crushing the spheroids, and the samples were analyzed on an inverted TMS-F microscope (Nikon). Infrared light was used for dark-field illumination, and green light was used for the stimulation of photomovements as described above. The tracks of the polystyrene beads were recorded with a CCD camera (C5985; Hamamatsu Photonics, Hamamatsu, Japan). Both the moving direction and speed of the fluid streamlines were calculated from the tracks of the polystyrene beads on the images.
A rotating filter system for pulsed light stimulation was constructed on the basis of the data of Foster and Smyth [28,75] using three 2-mm thick acrylic filters, F1 (#700; Sumitomo Chemical, Tokyo, Japan), F2 (#700, Sumitomo Chemical), and F3 (#702; Sumitomo Chemical), with transmissivities for green light of 74.4%, 74.4%, and 40.77%, respectively. Sectors of 28° (F1), 50° (F2) and 110° (F3) were cut out from the filters as calculated in Figure Figure7e,7e, and the sandwich construction was mounted reflection-symmetrically on a DC servomotor as shown in Figure Figure7b.7b. The sandwich construction resulted in four different transmissivities: T1 = 100% (gap, no filter); T2 = 74% (F1), T3 = 55% (F1 + F2), and T4 = 23% (F1 + F2 + F3). The filter system was rotated at 0.83 rps (49.8 rpm). The rotating filter system was placed into the light path of the green light that was used to stimulate the photomovements. The oscillating light intensity was recorded by a silicon photodiode sensor (S1336-8BQ; Hamamatsu Photonics) connected to an oscilloscope (Tektronix, Beaverton, OR); the highest recorded light intensity (28 μmol m-2 s-1) was set to 100%.
Flagellar waveforms were analyzed both with the CCD camera on the TMS-F microscope as described above using a long-pass filter with λT >610 nm for field illumination, and by high-speed microvideography as reported by Inouye and Hori . In the latter case, flagellar activity (at 20°C) was filmed at 200 frames per second using an MHS-200 high-speed video system (NAC Image Technology, Simi Valley, CA) attached to an Optiphoto light microscope (Nikon). The built-in strobe light of the high-speed video system was used to illuminate the field of view. Because the strobe light is indispensable for high-speed microvideography, the normal beating mode was recorded either right at the moment when the dark-adapted spheroids were illuminated with the strobe light, which corresponded to beating in the dark as the cells had no time to react, or after 10 s of illumination with the strobe light, which was several seconds after cells had adapted to the light.
The spheroids were flattened gently by placing a suspension of algae between a slide (without vinyl tape spacers) and a coverglass. The flattened spheroids were observed with bright-field illumination using an upright compound microscope (BHS; Olympus, Tokyo, Japan). The digital images were analyzed using NIH Image software to calculate the eyespot size, defined as the largest diameter of the eyespots, and to determine the linear distance between a given eyespot and the anterior pole . The anterior pole of the spheroid was identified as described earlier .
F: filter; n: sample size; PI: photoaccumulation index; SD: standard deviation; T: transmissivity.
NU performed experiments and analyzed data. SM designed experiments, performed experiments, and contributed reagents and materials. II designed experiments and coordinated the first phase of the research project. AH (corresponding author) evaluated the data, coordinated the second phase of the research project, constructed the figures and wrote the paper. All of the authors read and approved the final manuscript.
Phylogenetic relationship between Volvox rousseletii MI01 and other volvocine algae. This analysis is based on a combined data set of the psaA, psaB, and rbcL cDNA fragments from 47 volvocine species and/or strains. The unrooted tree was calculated by the neighbor-joining method using the PHYLIP software.
Description of the phylogenetic analysis of the Volvox rousseletii strain MI01 that was utilized in this study. The Volvox rousseletii strain MI01 utilized in this study was subjected to a molecular phylogenetic analysis. To do so, certain DNA fragments that were used in the phylogenetic analyses of other volvocine algae were cloned and sequenced, which included the chloroplast genes encoding the photosystem I P700 chlorophyll a apoprotein A1 (psaA), the photosystem I P700 chlorophyll a apoprotein A2 (psaB), ribulose bisphosphate carboxylase (rbcL) and the internal transcribed spacer sequence 2 (ITS2).
List of species, strains, abbreviations, accession numbers, and references for the psaA, psaB, rbcL and ITS2 sequences from volvocine species.
Sequence alignment of psaA cDNA fragments from several volvocine species.
Sequence alignment of psaB cDNA fragments from several volvocine species.
Sequence alignment of rbcL cDNA fragments from several volvocine species.
Comparison of psaA sequences from several volvocine species.
Comparison of psaB sequences from several volvocine species.
Comparison of rbcL sequences from several volvocine species.
Comparison of ITS2 sequences from several volvocine species.
We thank Takeshi Nakayama and other members of the Inouye lab, as well as Terumitsu Hori (sadly now deceased) and members of his lab, for their useful discussions and technical suggestions. We also acknowledge a useful discussion with Hisayoshi Nozaki. Finally, we thank Kordula Puls and Mina Nomizu for their technical assistance. This work was supported in part by a grant from the Toyobo Biotechnology Foundation and by a JSPS Postdoctoral Fellowship for Research Abroad (both to NU).